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Are in vitro metabolism and DDI studies critical for an IND?
AAPS 2019 Pharmsci 360, San Antonio, Texas04 November 2019
Booth 1206 Greg Loewen, Sekisui-XenoTech
gloewen@xenotechllc.com
Road Map
• IND – Short discussion • Guidance documents – IND and DDI • In Vitro Assays
– Permeability assays– Protein binding– Metabolic stability– Cross species metabolite identification
• Drug-drug interaction assessment– Reaction phenotyping– Inhibition– Induction– Drug Transporters
2
What is an IND?
• IND = Investigational New Drug • 21CFR Part 312 (Investigational New Drug Application) • Scope: “This part contains procedures and requirements
governing the use of investigational new drugs, including procedures and requirements for the submission to, and review by, the Food and Drug Administration of investigational new drug applications (IND's). An investigational new drug for which an IND is in effect in accordance with this part is exempt from the premarketing approval requirements that are otherwise applicable and may be shipped lawfully for the purpose of conducting clinical investigations of that drug.”
Link to eCFR 21Part3123
IND Content • Chemistry, Manufacturing, and Controls (CMC)
– Information on the drug substance and drug product pertaining to the composition, manufacturer, stability, and controls
• Clinical Protocols Investigator Information– Detailed protocols for clinical studies, qualifications of the clinical
investigators, commitments to obtain informed consent. Asses the potential to expose subjects to unnecessary risks.
• Pharmacology and Toxicology Information (Pharm/Tox)– Summary of toxicology findings (in vitro or animal studies) to support use in
humans– Description of the pharmacologic effects and mechanisms of action,
secondary pharmacology, safety pharmacology – Pharmacokinetics: Information on the absorption, distribution, metabolism
and excretion (ADME)
4https://www.fda.gov/drugs/investigational-new-drug-ind-application/investigator-initiated-investigational-new-drug-ind-applications
Guidance documents
5
M3(R2) Non clinical safety studies…
• Section III. TOXICOKINETIC AND PHARMACOKINETIC STUDIES – In vitro metabolic and plasma protein binding data for animals
and humans…should be evaluated before initiating human clinical trials
– …and in vitro biochemical information relevant to potential drug interactions should be available before exposing large numbers of human subjects or treating for long duration.
– compare human and animal metabolites…– Nonclinical characterization of a human metabolite(s) is only
warranted when ... greater than 10 percent of total drug-related exposure and at significantly greater levels in humans than the maximum exposure seen in the toxicity studies.
Link to the M3(R2) guidance6
Permeability (Absorption and Excretion) In vitro permeability to predict absorption,
bioavailability, tissue distribution and routes of excretion
• Test system: polarized cells grown on transwellplates
• Permeability measured in the A to B and B to A directions. Efflux Ratio > 2 indicates a transporter interaction
• Oral bioavailability: Determined by absorption and metabolism
• Absorption includes disintegration, dissolution and permeation
• Metabolism: first pass in the intestine and liver
• Bio Waiver: Waiver of in vivo bioavailability and bioequivalence… for class I compounds. Based on high solubility and high permeability
Test Systems
Caco-2 Human colorectal carcinoma derived cell line – intestinal permeability
MDCKII andLLC-PK1
Canine or porcine derived cell line -Passive permeability
MDCKII-MDR1LLC-PK1-MDR1
Transfected with human transporters – transporter interaction or tissue specific permeability
PAMPA Artificial membrane –passive permeability
Apical
Basal 7
8
Permeability, more than absorption BCS, BDDCS and ECCS
Class 1 High solubility Metabolism
Class 2 Low solubility Metabolism
Class 4 Low Solubility Elimination of Unchanged Drug
Class 3High Solubility Elimination of Unchanged Drug
Solubility Class 1AClearance:metabolism(≥70%).Eliminated asmetabolites(≥ 70%).Is absorption permeability limited: NO
Class 1BClearance: hepatic uptake(≥ 70%).Eliminated asmetabolites(≥ 70%).Is absorption permeability limited: NO
Class 2Clearance: metabolism(≥70%).Eliminated as metabolites (≥70%).Is absorption permeability limited: NO
Class 3AClearance:renal (≥70%).Eliminated asparent in urine(≥ 70%).Is absorption permeability limited: YES
Class 3BClearance:hepatic uptake orrenal (≥ 70%).Eliminated asparent in bile orurine (≥ 70%).Is absorption permeability limited: YES
Class 4Clearance:renal(≥70%).Eliminated as parent in urine (≥70%).Is absorption permeability limited: YES
Perm
eabi
lity/
Met
abol
ism
High
Per
mea
ble
Low
Per
mea
ble
Acids/Zwitterions Bases/Neutrals
Adapted from: BCS: Amidon, 1995 BDDCS: Wu and Benet, 2005 ECCS: Varma et. Al., 2015
Plasma Protein Binding (Distribution) Used to predict the free fraction (unbound) of the drug in circulation in
pre-clinical species and humans
•Free Drug: In most cases, only free drug interacts with a target (or off target)
•Fraction unbound can be used to predict the human dose from in vitro and pre-clinical models
•Toxicity: Exposure in the toxicological species can be related to the human exposure
•DDI: Free fraction is used in most of the in vitro DDI predictions to determine if a clinical DDI experiment is needed (Di et. al., Jphamsci, 2017)
•Red Blood Cell Partitioning: Important if the ratio is not 1 •α-1-acid glycoprotein and Albumin binding: important in certain disease
states
9
Plasma Protein Binding (Methods) Equilibrium Dialysis Compound Equilibrates across membrane
RED device 96 well plate with 48 samples Dialysis membrane (MWCO 8K, 12K)Multiple sampling
Ultrafiltration Centrifugation to apply 2000g
Fast process (good for low stability compounds)
UltraCentrifugationSpike test article in plasma
Centrifuge ~ 500,000 g for 5-6 hours at 37CLong process Low NSB
10
Metabolism (Metabolism and Excretion)
• Routes of clearance – Metabolic stability comparison of human and pre-clinical
species– Predication of human clearance
• Metabolic Stability: Are major routes of metabolism non-CYP mediated (e.g., does the clearance in microsomes match in vivo)?– AO? Use pooled human liver cytosol, hepatocytes OR S9 ±
Hydralazaine and ± 1-ABT– FMO? Use pooled HLM ± heat inactivation of FMO– UGTs? Use HLM with and without UDPGA– SULTs? Use S9 with PAPS
• May need to consider transporters
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Metabolite characterizationTiming of in vitro studies –
• ICH M3(R2), “In vitro metabolic … data for animals and humans…”
• In Vitro DDI guidance: FDA suggests metabolite characterization studies precede reaction phenotyping
• “Metabolic pathway identification experiments identify the number and structures of metabolites produced by a drug . . . Data obtained from metabolic pathway identification experiments help to determine whether and how to conduct a reaction phenotyping study”
• Also consider the FDA’s 2016 MIST guidance
Timing of metabolite characterization studies –
• Soft spot analysis from in-vitro samples Discovery• In Vitro hepatocyte incubation, cross species metabolism • In vivo samples from pre-clinical species Pre-clinical • Clinical samples (non radio-labeled)• Pre-clinical ADME study with radio-labeledPhase I• Human AME study – quantitative assessment • Synthesize metabolites for quantification by LC/MS (earlier?)Phase II
• Monitor metabolites in clinical studiesPhase III
13
In vitro metabolite profiling experiments • Incubate parent drug with appropriate test system• Separate metabolites and matrix components by
extraction and/or chromatography• Detect metabolites by various techniques
– Optical spectrophotometric detection (UV/vis, fluorescence)
– Radiometric detection (14C, 3H, 35S)– Mass spectrometric detection
• Perform structural elucidation of detected components with mass spectral data
14
Does MS signal equal abundance? TIC of +MRM (14 pairs): Exp 1, from Sample 3 (Dog, T=4, rep 2) of RD_Prop_05Dec10.wiff (Turbo Spray), Smoothed Max. 4.7e4 cps.
2 4 6 8 10 12 14 16 18 20 22 24 26Time, min
0.0
5000.0
1.0e4
1.5e4
2.0e4
2.5e4
3.0e4
3.5e4
4.0e4
4.5e44.7e4
Intensi
ty, cps
15.3
15.9
12.2 14.5
13.0
Propranolol
Glucuronides
OH + Sulfate
OH + Glucuronide
OH + Glucuronide
N-dealkylation
Hydroxylation
15
Does MS signal equal abundance? NOBRAM from Sample 18 (Dog, T=4, rep 2) of RD_Prop_03Dec10.wiff, Smoothed, Smoothed, Smoothed Max. 7.8 counts.
0 2 4 6 8 10 12 14 16 18 20 22 24 26Time, min
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
6.0
6.5
7.0
7.57.8
BRAM
, count
s
15.3
15.8
2.0
11.7 12.216.1 19.412.9 22.0
Propranolol
Glucuronide
OH + Glucuronide
OH + Sulfate
Hydroxylation
N-dealkylation
OH + Glucuronide
16
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Example data output, Repaglinidehigh-resolution LC UV chromatogram (254)
Time6.00 8.00 10.00 12.00 14.00 16.00
AU
-1.0e-3
0.0
1.0e-3
2.0e-3
3.0e-3
4.0e-3
5.0e-3
6.0e-3
7.0e-3
8.0e-3
9.0e-3
RD117007_MSE_05Apr12_014 Sb (3,40.00 ); Sm (SG, 40x1) 4: Diode Array 254
Range: 1.078e-28.77
9.94
50 µM Repaglinide2.0 mg/mL HS930 minutes; 35°C; pH 7.4NADPH-generating system
Repaglinide
Hydroxyrepaglinide(M4)
Repaglinide desaturationmetabolitesRepaglinide
dicarboxylic acid metabolite (M2)
Unlabeled peaks are not related to repaglinide
Ring-opened alcohol metabolite
Major in vivo metabolite
High abundance Low abundance
Barbara, internal data, 2013
18
Example data output, Repaglinidemetabolite profile by mass spectrometry
Component m/z value Mass shift Proposed biotransformation
C1 (M0-OH) 469 +16 Hydroxylation
C2 451 -2 Dehydrogenation
C3 469 +16 Oxygenation
C4 (M4) 469 +16 Oxygenation
C5 (M1) 385 -68 N,N-didealkylation
C6 441 -12 O-deethylation + oxygenation
C7 (M5) 425 -28 O-deethylation
C8 469 +16 Oxygenation
C9 469 +16 Oxygenation
C10 471 +18 Oxygenation+ reduction
C11 (M2) 485 +32 N-dealkylation + oxidation to the acid
C12 451 -2 Dehydrogenation
C13 451 -2 Dehydrogenation
C14 451 -2 Dehydrogenation
Barbara, internal data, 2013
Accurate mass for biotransformation assignmentNominal
mass shift (amu)
Biotransformation(s) Elemental composition change
Accurate mass shift (amu)
+14Oxidation + dehydrogenation +O -2H +13.9792
Methylation +CH2 +14.0157
+16Oxidation
+O +15.9949Heteroatom dealkylation within a heterocycle
+18Oxidation + hydrogenation +O +2H
+H2O+18.0106
Hydrolysis
+28
2x (Oxidation + dehydrogenation) +2O -4H +27.9584Oxidation + dehydrogenation +
methylation +O -2H +CH2 +27.9949
Di-methylation or ethylation +2(CH2) +28.0313
+32Di-oxidation +2O +31.9898
Oxidation + hydrogenation + methylation +O +2H +CH2 +32.0263
19
20
Example MS/MS fragmentation data, Lapatanib metabolite suspected of mechanism based inhibition
Barbara et. al., DMD, 2013
Timing of In vitro Pharmacokinetic DDIs
• 2017 FDA guidance on In Vitro DDI • Section III. Evaluating Metabolism-Mediated Drug
Interactions: – Reaction Phenotyping, CYP inhibition and CYP induction– “sponsors should initiate in vitro metabolic studies before” first-
in-human studies• Section IV. Evaluating Transporter-Mediated Drug
Interactions – “The timing of the in vitro evaluation of each transporter may
vary depending on the therapeutic indications of the investigational drug.”
• Note: Also covered in EMA 2013 (final), and PMDA 2018 (final)
21
Reaction Phenotyping• “The sponsor should routinely evaluate CYP1A2, CYP2B6, CYP2C8, CYP2C9,
CYP2C19, CYP2D6, and CYP3A4/5 using in vitro phenotyping experiments…”
• “…undergoes significant in vivo metabolism that is not mediated by these major CYP enzymes.”
– CYP2A6, CYP2J2, CYP4F2, and CYP2E1, Phase I (MAO, FMO, XO and AO) Phase II (UGTs)
• In vitro phenotyping experiments, Monitor:– metabolite formation (if available) – OR loss of substrate (assuming sufficient turnover)
• Time and protein to determine initial rate conditions • Inhibition (chemical or antibody) • Recombinant CYP enzymes • Optional: KmVmax (for metabolite formation), fm and correlation analysis
22
The sponsor should develop validated and reproducible analytical methods to measure levels of the parent drug and each metabolite” (line 750)
Reaction Phenotyping (continued) Recombinant CYP enzymes Chemical or Antibody Inhibitors
23
Inhibition of metabolizing enzymes • “The sponsor should evaluate an investigational
drug’s potential to inhibit CYP1A2, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6, and CYP3A4/5 in both a reversible manner (i.e., time-dependent inhibition (TDI)).”
• Follow up with Ki (direct inhibition) or KIKinact for TDI. Can skip the Ki with a well designed experiment (Haupt et. al., 2015)
• Other enzymes? UGT when the compound is metabolized by UGT Microsomes, hepatocytes or recombinant enzymes
• Selective probe substrates (validated), short incubation times and low protein concentrations
24
Induction of metabolizing enzymes • “The sponsor should evaluate the potential of
an investigational drug to induce” CYP1A2, CYP2B6, and CYP3A4/5 and follow-up with CYP2C8, CYP2C9 and CYP2C19 IF CYP3A/5 is induced
• End pointes include mRNA and/or CYP enzyme activity (EMA requires mRNA).
– But! For the CYP2Cs, mRNA does not work well, especially CYP2C19
• Hepatocytes from 3 donors (fresh or cryopreserved)
• Test article concentration in the culture media (spent media analysis)
– Adjust dosing?
• Toxicity of the test article on the test system
EC50 = 0.58 µMEmax = 6.1 fold
25
Drug Transporters Transporters are membrane bound proteins that
govern the transport of compounds in and out of cells
In the intestine and at the BBBefflux (ABC) transporters predominate
(particularly P-gp and BCRP)regulating absorption or entry into the brain
In the liver (hepatocytes) and kidney (proximal tubules) uptake transporters (SLC) remove
compounds from the blood and efflux (ABC) or SLC transporters pump them into the bile or urine
If your compound is a substrate or
inhibitor of transporters, it can be involved in a PK
based DDIFigures adapted from Zamek-Gliszczynski et al., Clin Pharm Ther 92:5 2012
26
Drug Transporters (Section IV of DDI guidance)
Transporters involved in DDI• ABC (Efflux): P-gp, BCRP• SLC (Uptake): OATP1B1, OATP1B3, OAT1, OAT3, OCT2, MATE1, MATE2-K• Others: BSEP, MRP2, OCT1 (and others as needed)
Transporter substrate (Victim) • P-gp and BCRP are typically tested early (pre IND)• SLC transporters: depends on route of elimination (post IND)• Study designs and test systems can vary
Transporter inhibition (Perpetrator)• Screens of all transporters done early (pre IND) • Follow up with IC50s as needed
27
In Vitro DDI comments • Equations in the guidance document(s) to determine if a clinical DDI is
needed – Some variation between the FDA, EMA and PMDA
– Poster co-authored by Dr. Brian Ogilvie and Dr. Andrew Parkinson
• Generally for inhibition and induction (perpetrator potential), if the relevant clinical concentrations are not known, tested concentrationsshould be limited by solubility and toxicity
• For substrate studies (victim potential), tested concentrations should be philologically relevant taking into consideration bioanalytical limitations and saturation of the enzyme in the test system
• Metabolites may need to be tested for potential DDI in vitro
28
Final Thoughts
• So, Are in vitro metabolism and DDI studies critical for an IND? – Metabolism: Yes– DDI studies, according to DDI guidance – YES
• DDI risk assessment is important when dosing patients with poor safety profile
• Useful for modeling PK and dose prediction for clinical study design
– Depending on the program, lack of these data may or may not result in a clinical hold
• What if the DDI studies were conducted prior to the release of the latest guidance document? – May or may not be accepted by the regulatory agencies
• What do our clients say?
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Thank You
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